WO2023111250A1 - Adapting the beam of a lighting module according to the load carried by a vehicle - Google Patents

Abstract

The invention relates to a method for controlling a matrix array light source of a near-field illumination module of a vehicle, the method comprising the following operations: - obtaining (601; 602) a vertical position of the lighting module; - modifying (604) a nominal command to supply the matrix-array light source with power on the basis of the vertical position obtained; - transmitting (605) the modified command for controlling the matrix array light source.

Description

Description

Adaptation of the beam of a light module according to the load of a vehicle

The present invention relates to the field of controlling a light module, in particular a near-field projection module in the side or rear position of a motor vehicle. More specifically, the invention relates to a method for controlling the power supply of a matrix-type light source as well as an associated control device.

[0002] It is becoming more and more common to use light sources with semiconductor elements, such as light-emitting diodes, LEDs, to perform various light functions of a vehicle. These functions may, for example, include daytime running lights, position lights, direction indicators or dipped beam headlights. The use of these small light sources with high luminosity and reduced power consumption also makes it possible to produce original light contours in a compact system and with reduced electrical energy. A pixelated light source, typically offered in the form of a matrix comprising a large number of light-emitting diodes controlled individually, also makes it possible to create very varied beams: depending on the control chosen, a matrix source can, for example, project an outline or pattern on the road, generate a combination of high beam (HB) and low beam (LB), or provide dynamic and directional lights.

[0003] Other pixelated sources can be based on technology other than LEDs. In particular, pixelated sources with micro-mirrors (DMD, for “Digital Micromirror Device” in English) or monolithic sources are known.

[0004] The near field projection light modules, or NFP for "Near Field Projection" in English, can be used on the side or rear parts of a motor vehicle, in particular at the height of the wheels of the vehicle, in order to project the light on the ground near the motor vehicle. Such a projection can perform a lighting function, a signaling function and/or a aesthetic. Such light modules are generally secured to the body of the vehicle.

[0005] The load of the motor vehicle, as well as its distribution, cause the vertical position of a near-field projection light module to vary. Such a variation relative to a nominal position induces defects in the light beam projected on the ground. Such defects can be linked to a deformation of the projected beam or to light intensity inhomogeneities in the projected beam.

The present invention improves the situation.

To this end, a first aspect of the invention relates to a method for controlling a matrix light source of a near-field projection light module of a vehicle, the method comprising the following operations: a. obtaining a vertical position of the light module; b. modification of a nominal supply command of the matrix light source according to the vertical position obtained; vs. Modified command transmission for matrix light source control.

[0008] Taking into account the vertical position of the light module makes it possible to compensate for the faults induced by a variation in the load of the vehicle.

[0009] According to one embodiment, the method may further comprise, upon detection of a modification of the vertical position of the light module, an update of the modification of the nominal power supply command.

[0010] Thus, the correction of the faults induced by the variations in the load of the vehicle is updated dynamically.

According to one embodiment, the vertical position of the light module can be determined: a. based on information from a sensor dedicated to the light module; b. from information relating to a shape of a beam of lighting projected by the vehicle, from camera data; and or vs. based on inclination information from a vehicle lighting module.

[0012] The sensor dedicated to the light module can for example be an inclinometer. The use of a sensor dedicated to the light module makes it possible to improve the precision associated with the determination of the vertical position, and therefore that of the modification of the nominal power supply command. The inclination information and that relating to the shape of a beam of lighting projected by the vehicle from a camera, allow for their part the determination of the vertical position without requiring the addition of a sensor in the vehicle.

In an exemplary embodiment, the matrix light source is a light source comprising a plurality of light-emitting emitters arranged in a matrix, each of the emitters being selectively and independently controlled to emit an elementary light beam. Examples of light-emitting elements include the light-emitting diode or LED, the organic light-emitting diode or OLED, or the polymeric light-emitting diode or PLED ( English acronym for "Polymer Light-Emitting Diode"), or the micro-LED.

[0014] Preferably, the matrix light source comprises at least one matrix of monolithic light-emitting elements, also called monolithic matrix. In a monolithic matrix, the light-emitting elements are grown from a common substrate and are electrically connected so as to be selectively activatable, individually or by subset of light-emitting elements. The substrate can mainly be made of semiconductor material. The substrate may comprise one or more other materials, for example non-semiconductors. Thus each electroluminescent element or group of electroluminescent elements can form a luminous pixel and can emit light when its or their material is supplied with electricity. The configuration of such a monolithic matrix allows the arrangement of selectively activatable pixels very close to each other, compared to conventional light-emitting diodes intended to be soldered on printed circuit boards.

[0015]According to one embodiment, the nominal command may comprise an activation of a first set of pixels of the light module and the modification of the nominal command may comprise the modification of the first set of pixels.

[0016] It is thus made possible to correct deformations of the projected light beam caused by the variation in vertical position of the near-field projection light module.

According to one embodiment, the nominal command comprises the activation of a first set of pixels of the light module by a pulse width modulation power supply, the nominal command comprising a duty cycle value for each pixel of the first set.

According to one embodiment, the modification of the nominal command may comprise the modification of at least one duty cycle of a pixel of the first set so as to harmonize a light intensity of a beam projected by the light module. It is thus made possible to correct defects of inhomogeneity of the light beam projected by the light module and caused by a change of vertical position.

[0019] In addition or as a variant, the modification of the nominal command comprises the modification of the first set of pixels into a first modified set of pixels, distinct from the first set corresponding to the nominal supply command, the first modified set comprising additional pixels relative to the first set of pixels. It is thus made possible to maintain the light beam projected identical to or close to the light beam projected from the nominal supply setpoint when the light module is in the nominal vertical position, and this despite the change in vertical position of the light module. In this example, the matrix light source comprises the first set of pixels corresponding to the nominal power supply command and a second set of pixels comprising the additional pixels, at least some of which will potentially be lit by the modification of the nominal command. power supply. The activation of the additional pixels can consist of applying electrical signals to these pixels such as the electrical current or the electrical current and a duty cycle. In the latter case, the value of the duty cycle can be a non-zero value, equal to or less than 100%.

According to one embodiment, the method is implemented in a vehicle comprising at least a first near-field projection light module comprising a first matrix source, and a second near-field projection light module comprising a second source matrix, a first vertical position can be determined for the first light module and/or a second vertical position can be determined for the second light module, a first nominal command can control the first matrix source and a second nominal command can control the second source matrix, the light module may be capable of projecting a first light beam as a function of the first nominal command and the second light module may be capable of projecting a second light beam as a function of the second nominal command, the first nominal command and/or the second nominal command can be modified so as to reduce the light intensity of a zone of superposition of the first and second projected light beams, as a function of the first vertical position and/or of the second vertical position.

[0022] It is thus made possible to correct defects of light intensity inhomogeneities caused by a modification of the superposition of projected light beams from different light modules.

[0023] In addition or as a variant, the first nominal command may comprise the activation of a first set of pixels of the first matrix source by a pulse-width modulation supply, and the second nominal command may comprise activating a second set of pixels of the second matrix source by a pulse-width modulated supply, the first nominal command and/or the second nominal command may be modified so as to decrease the ratio cyclic of pixels corresponding to the overlapping area, in order to decrease the light intensity of the overlapping area.

Thus, the correction of the defects due to the modification of the superposition zone of the light beams is carried out without modifying the power source of the pixels of the matrix light sources, only the duty cycles being modified.

[0025] In addition or as a variant, the first nominal command can be modified according to: a. from the first vertical position; or b. the first vertical position and the second vertical position.

[0026] Taking into account the vertical positions of several modules makes it possible to improve the precision associated with the compensation of the defects of the projected light beams. In particular, it makes it possible to adapt the light beams according to the distribution of the load in the vehicle.

According to one embodiment, the method can be implemented in a vehicle comprising at least two near-field projection light modules, including a right side light module comprising a right matrix source and a left side light module comprising a left matrix source, a right vertical position can be determined for the first light module and a second left vertical position can be determined for the second light module, a right nominal command can control the right matrix source and a left nominal command can control the source matrix left, the right side light module may be capable of projecting a right side light beam depending on the first nominal command and the light module may be capable of projecting a left side light beam depending on the second nominal order; the right nominal command can be changed according to the right vertical position and the left nominal command is changed according to the left vertical position.

[0028] Thus, the side light modules can be controlled independently, which makes it possible to take into account not only the load of the vehicle, but also its distribution, since an asymmetry in the distribution of the load can then be taken into account.

A second aspect of the invention relates to a device for controlling a matrix light source of a near-field projection light module, the device comprising a processor configured for a. obtain a vertical position of the light module; b. modify a nominal supply command of the matrix light source according to the vertical position obtained; vs. transmit the modified command for control of the matrix light source.

Another aspect of the invention relates to a vehicle, in particular a motor vehicle, comprising a control device according to the invention.

Other characteristics and advantages of the invention will appear on examination of the detailed description below, and of the appended drawings in which:

[0032] [Fig 1] illustrates a motor vehicle comprising three near-field projection light modules according to one embodiment of the invention, in nominal vertical positions;

[0033] [Fig 2a] illustrates a side view of a vehicle comprising near field projection light modules according to one embodiment of the invention in nominal vertical positions;

[0034] [Fig 2b] illustrates a side view of a vehicle comprising near-field projection light modules according to one embodiment of the invention, in vertical positions different from the nominal vertical positions; [0035] [Fig 3a] shows the activation of pixels of the matrix light source of a near-field projection light module, according to one embodiment of the invention when the light module is in a nominal vertical position;

[0036] [Fig 3b] shows the activation of pixels of the matrix light source of a near-field projection light module, according to the prior art, when the light module is not in its nominal vertical position;

[0037] [Fig 3c] shows the activation of pixels of the matrix light source of a near-field projection light module, according to one embodiment of the invention, when the light module is not in its nominal vertical position;

[0038] [Fig 4] illustrates a vehicle according to the same view as that of Figure 1, when the vehicle is loaded and the vertical positions of the light modules are different from the nominal vertical positions;

[0039] [Fig 5a] illustrates the activation of matrix light source pixels of two near-field projection light modules in nominal vertical positions, according to one embodiment of the invention;

[0040] [Fig 5b] illustrates the activation of pixels of matrix light sources of two near-field projection light modules, in vertical positions corresponding to a first loading level of the vehicle, according to an embodiment of the invention;

[0041] [Fig 5c] illustrates the activation of matrix light source pixels of two near-field projection light modules, in vertical positions corresponding to a second loading level of the vehicle, different from the first loading level, according to an embodiment of the invention;

[0042] [Fig 6] is a diagram illustrating the steps of a method for controlling a matrix light source of a near-field projection light module according to one embodiment of the invention;

[0043] [Fig 7] illustrates a device for controlling a matrix light source according to one embodiment of the invention. [0044] The description focuses on the characteristics that set the method or system apart from those known in the state of the art. The operation and manufacture of pixelated or matrix light sources, or of light-emitting diodes will not be described in detail since it is known per se in the state of the art. For example, it is known to propose matrices comprising hundreds or thousands of semiconductor components of the micro-LED type, or else to manufacture a monolithic pixelated source, by forming the light-emitting semiconductor elements during a process of common layer deposition.

[0045] Although the electrical characteristics of the light-emitting diodes that make up such a matrix may vary, it is reasonable to assume that a prior calibration (e.g. a control calibrated to take into account variations in load current) is carried out at the time of the manufacture of the pixelated source, or during its assembly during the assembly of the light module.

Figure 1 illustrates a motor vehicle 100 comprising three light modules 101.1, 101.2 and 101.3 near field projection according to one embodiment of the invention in nominal vertical positions.

No restriction is attached to the number of light modules that can include a vehicle according to the invention. The vehicle 100 can thus comprise any number of near-field projection light modules greater than or equal to 1. In the following, the example of three near-field projection light modules is described, for illustrative purposes only. In the following, the expression “light module” refers to a near-field projection light module, unless explicitly stated otherwise.

The vehicle 100 comprises in particular: a. a left side light module 101.1 comprising a left matrix light source 102.1 and capable of projecting a left side light beam 103.1 close to the vehicle 100; b. a right side light module 101.2 comprising a right matrix light source 102.2 and capable of projecting a right side light beam 103.2 close to the vehicle 100; etc. a rear light module 101.3 comprising a rear matrix light source 102.3 and capable of projecting a rear light beam 103.3 close to the vehicle 100.

The left side light module 101.1 and the rear light module 101.3 can be configured so that the left side light beam 103.1 and the rear light beam 103.3 are superimposed in a first superposition zone 104.1.

The right side light module 101.2 and the rear light module 101.3 can be configured so that the right side light beam 103.2 and the rear light beam 103.3 are superimposed in a first superposition zone 104.2.

The light modules 101.1, 101.2 and 101.3 can in particular be configured so that, in nominal positions, the light intensity is homogeneous between the parts of the light beams which are located in the overlapping zones 104.1 and 104.2 and those which do not are not.

[0052] No restriction is attached to the shape, size or position of the overlapping zones. In addition, no restriction is attached to the number of overlapping zones, which depends on the number of light modules, their respective positions, the light beams projected as well as the vertical position of each light module.

No restriction is attached to the distribution of near-field projection light modules on the vehicle. For example, the vehicle 100 can comprise several modules at the rear or several side modules on the same side, on the right or on the left. [0054] Figure 2a illustrates a side view of a vehicle comprising near field projection light modules according to one embodiment of the invention in nominal vertical positions.

[0055] In particular, the left light module 101.1 and the rear light module

101.3 of Figure 1 are shown in Figure 2a. Note that the vehicle 100 may also include the right light module 101.2 shown in Figure 1.

In Figure 2a, the left light module 101.1 is in a first nominal vertical position 200.1 and the rear light module 101.3 is in a second nominal vertical position 200.3.

In Figure 2a, the second nominal vertical position 200.3 is greater than the first nominal vertical position, for illustrative purposes only. No restriction is attached to the respective values of the nominal vertical positions of the light modules of the vehicle 100.

By nominal vertical position is meant a vertical position for which a light module is configured by default to project a light beam without deformation. The light module can thus control the supply of its default matrix source according to a nominal command. Such a command can for example consist in activating a first set of pixels of the matrix light source.

The nominal vertical position of a light module can correspond to the vertical position of the module when the load of the vehicle 100 is zero.

[0060] Figure 2b illustrates a side view of a vehicle comprising near-field projection light modules according to one embodiment of the invention, in vertical positions different from the nominal vertical positions.

In particular, the left side light module 101.1 can be in a left vertical position 201.1 different from the nominal left vertical position 200.1 and the rear side module 101.3 can be in a rear vertical position.

201.3 different from the rear nominal vertical position 200.3. Such a difference can in particular be caused by a non-zero load of the vehicle 100, due for example to the weight of passengers and/or objects.

In practice, the difference between a vertical position of a light module when the vehicle is loaded, and its nominal vertical position, can be significant, in particular of the order of several tens of percent of the value of the vertical position. nominal.

[0063] For example, the vertical position of the light module when the vehicle is loaded may be less than 70% of the nominal vertical position, or even approximately equal to 50% of the nominal vertical position, in particular for the side light modules. 101.1 and 101.2.

Such a difference induces visible defects in the light beam projected on the ground by a near-field projection light module, as will be better understood on reading what follows.

A first example of a fault induced by the variation in the vertical position of a light module is the deformation of the light beam projected on the ground, as illustrated in FIGS. 3a, 3b and 3c.

Figures 3a to 3c indeed show the activation of pixels of the matrix light source of a near-field projection light module, for different loading levels of the vehicle 100.

A matrix source 102 of rectangular shape comprising eight rows of light pixels 300 and twenty-one columns of light pixels 300 is represented in FIGS. 3a to 3c, by way of illustration. However, no restriction is attached to the number of pixels 300 of the matrix light source 102 nor to the shape of the matrix source 102. For example, the matrix source 102 can comprise any number of columns and any how many rows of pixels. In addition, the columns and/or the rows of pixels can comprise different numbers of pixels so as to produce shapes different from a rectangle or a square.

In Figure 3a, the light module comprising the matrix source 102 is in a nominal vertical position. The supply of the matrix source 102 is then controlled by a nominal supply command, which provides for the activation of a first set 301 of pixels among the set of pixels 300 of the matrix source 102.

No restriction is attached to the format of the nominal power supply command, which can identify the pixels of the first subset, by their coordinates in the matrix source 102, or by a unique identifier. In addition, the power supply to each pixel can be pulse-width modulated, so as to individually control the intensity of the light rays emitted by each pixel.

A projected light beam 310 is then obtained. In FIG. 3a, the projected light beam 310 has a rectangular shape which corresponds to a nominal shape.

In Figure 3b, the light module comprising the matrix source 102 is in a vertical position different from the nominal vertical position.

However, the matrix source 102 is still controlled by the nominal power supply command, in accordance with the prior art. The variation in the vertical position of the light module thus induces a deformed projected light beam 320 with respect to the light beam 310 of nominal shape.

In Figure 3c, the light module comprising the matrix source 102 is in the same vertical position as in Figure 3b, that is to say a vertical position distinct from the nominal vertical position.

However, according to the invention, the power supply control used is modified with respect to the nominal power supply control, depending on the vertical position of the light module. Thus, the modification of the power supply control is determined from the vertical position of the light module, which makes it possible to compensate for the defects induced by the variation of the vertical position of the light module. In the example of FIG. 3c, the nominal power supply command is modified so as to modify the first set of pixels 301 into a first modified set 302 of pixels, distinct from the first set 301 corresponding to the nominal power supply command. In particular, the first modified set 302 comprises additional pixels with respect to the first set 301, so that the projected light beam 330 is identical to, or close to, the projected light beam 310 from the nominal power supply setpoint when the light module is in the vertical position nominal.

The shape and the number of pixels of the first set 301 and of the first modified set 302 are given for illustrative purposes only.

The light module, or more generally the matrix light source supply control device, can store a modified supply command for each vertical position, or for each interval of vertical positions. Alternatively, the light module dynamically calculates the modified power command based on the determined vertical position.

[0078] Figure 4 illustrates the vehicle 100 according to the same view as that of Figure 1, when the vehicle is loaded and the vertical positions of the light modules 101.1, 101.2 and 101.3 are different from the nominal vertical positions. The vertical position of at least one light module is different from its nominal vertical position. In what follows, and by way of illustration only, it is considered that the vertical positions of the three light modules 101 .1 , 101 .2 and 101 .3 differ from their respective nominal vertical positions.

The variation in vertical position induces another type of defect than that illustrated in FIG. 3, namely areas of luminous inhomogeneity.

[0080] Indeed, the variation of the vertical position of the left side light module

101.1 induces a modification of the projected light beam 403.1, compared to the projected light beam 103.1 of FIG. 1, in particular a narrowing, due to the bringing together of the left side light module 101.1 with respect to the ground.

[0081] Similarly, the variation in the vertical position of the right side light module

101.2 induces a modification of the projected light beam 403.2, compared to the projected light beam 103.2 of FIG. 1, in particular a narrowing, due to the bringing together of the right side light module 101.2 with respect to the ground. Finally, the variation of the vertical position of the rear light module 101.3 induces a modification of the projected light beam 403.3, compared to the projected light beam 103.3 of FIG. 1, in particular a narrowing, due to the bringing together of the rear light module 101.3 by relation to the ground.

This results in a modification of the superposition zones 104.1 and 104.2 presented in FIG. 1 into a first modified superposition zone 404.1 between the projected light beams 403.1 and 403.2 and a second modified superposition zone 404.2 between the projected light beams 403.2 and 403.3.

[0084] In particular, each modified overlapping zone is narrowed compared to the nominal overlapping zones 104.1 and 104.2 illustrated in FIG.

The modification of the overlapping zones into modified overlapping zones 404.1 and 404.2 leads to an increase in the luminosity in these overlapping zones. This results in an inhomogeneity of the projected light beams 403.1, 403.2 and 403.3 between the parts of the light beams 403.1, 403.2 and 403.3 in the modified superposition zones 404.1 and 404.2, and the parts of the light beams 403.1, 403.2 and 403.3 outside the zones modified overlays 404.1 and 404.2. Such heterogeneities thus constitute defects in the projected light beams which are induced by variations in the vertical positions of the light modules of the vehicle 100.

[0086] Figures 5a to 5c illustrate the activation of pixels of matrix light sources of two near-field projection light modules, for different loading levels of the vehicle 100.

FIG. 5a illustrates the nominal supply commands respectively applied by the left side light module 101.1 and by the rear light module 101.3 to their respective matrix light sources 102.1 and 102.3.

[0088] The nominal power controls illustrated in Figure 5a designate a first set of pixels 301.1 of the left side light source 102.1 and a second set of pixels 301.2 of the rear light source 102.3. In the example of Figure 5a, the light sources 102.1 and 102.3 are identical and the first and second sets 301.1 and 301.2 are symmetrical. However, no restriction is attached to the respective numbers of pixels of the light sources 102.1 and 102.3, to their respective distributions, nor to the first and second sets 301.1 and 301.2 defined by the nominal power supply commands.

In Figure 5a, the pixels of each light source are powered by pulse width modulation, or PWM for "Pulse Width Modulation" in English. Thus, the same source can supply pixels to obtain variable light intensities between pixels. For this purpose, a duty cycle between 0 and 100 can be defined and controlled for each pixel of the first set 301.1 and of the second set 301.2 for each pixel, in the respective power controls.

The principle of power supply by pulse width modulation is well known and is not described further in what follows.

The duty cycle values of a group 501.1 of pixels of the first set 301.1 are represented in FIG. 5a, and are values defined by the nominal power supply command associated with the left side light source 102.1. The duty cycles of the other pixels of the first set 301.1 are not described, for the sake of simplification.

The duty cycle values of a group 501.3 of the second set 301.2 are represented in FIG. 5a, and are values defined by the nominal power supply command associated with the rear light source 102.3. The duty cycles of the other pixels of the second set 301 .2 are not described, for the sake of simplification.

The groups 501.1 and 501.3 correspond to the pixels whose light rays are superimposed in the modified superposition zone 404.1 when the load of the vehicle 100 increases. FIG. 5b illustrates the modifications of the nominal power controls of the left side light source 102.1 and of the rear light source 102.3, for a first level of vehicle loading, according to an embodiment of the invention .

The modifications applied to the nominal power supply commands make it possible to compensate for the faults illustrated with reference to FIG. 4, by reducing the light intensity of the modified superposition zone 404.1 so that it is homogeneous with the rest projected light beams 403.1 and 403.3. For this purpose, the nominal power commands are modified so as to decrease the values of the duty cycles of the pixels of the groups 501.1 and 501.2.

The modifications applied to the nominal supply controls are determined from the respective vertical positions of the left side light module 101.1 and of the rear light module 101.3, which depend on the first loading level.

[0098] In particular, the modification of the nominal supply control of the left side light source 102.1, can be determined from: a. the vertical position of the left side light module 101.1; or b. the vertical position of the left side light module 101.1 and the vertical position of the rear light module 101.3. This embodiment makes it possible to improve the precision associated with the correction of the defects of the projected light beams.

FIG. 5c illustrates the modifications of the nominal supply controls of the left side light source 102.1 and of the rear light source 102.3, for a second loading level of the vehicle, higher than the first loading level, according to a embodiment of the invention.

[0100] The modifications applied to the nominal power supply commands make it possible to compensate for the defects illustrated with reference to FIG. 4, by reducing the light intensity of the modified superposition zone 404.1 so that it is homogeneous with the rest projected light beams 403.1 and 403.3. AT Note that the size of the modified 404.1 overlay area varies between the first and second loading levels. Indeed, the higher the loading level, the more the overlap zone shrinks.

To this end, the nominal supply commands are modified so as to reduce the values of the duty cycles of the pixels of the groups 501.1 and 501.2. The duty cycles are even more reduced than in the case of FIG. 5b, since the vertical positions of the light modules 101.1 and 101.3 are lower than those of these same light modules in FIG. 5b. Figures 5b and 5c thus make it possible to illustrate the consideration of the vertical positions of the light modules in the determination of the modifications made to the nominal power supply commands of the light sources.

FIG. 6 is a diagram illustrating the steps of a method for controlling a matrix light source according to one embodiment of the invention.

The method according to the invention can be implemented in a device for controlling a matrix light source. The control device can be integrated into a near-field projection light module comprising the matrix light source, such as one of the light modules 101.1, 101.2 and 101.3 described above.

[0104] In a step 601, the control device receives information from sensors, such as: a. information from a sensor dedicated to the light module. Such a sensor can be of the inclinometer type, or any other technology allowing direct access to the vertical position of the light module. Such a sensor makes it possible to improve the precision associated with the determination of the vertical position, as well as the responsiveness associated with such a determination. The dedicated sensor can be integrated into the light module; b. information relating to a shape of an illumination beam projected by the vehicle, based on camera data. Indeed, the inclination of the vehicle's headlights varies the shape of the lighting beam. Such an inclination also makes it possible to know the inclination of other elements of the vehicle, such as the side or rear light modules. The front headlight inclination data can be received by the light module which can thus deduce its vertical position. Since a camera filming the road in front of the vehicle is available in most vehicles, such an embodiment does not require additional sensors; and/or c. inclination information from a vehicle lighting module. Such information is also called “leveling” information and is generally accessible in any type of vehicle, which avoids having to resort to additional sensors. The tilt position of the light module can be deduced from such information.

In a step 602, the control device deduces from the information received its vertical position, and possibly the vertical position of at least one other light module.

In a step 603, the control device determines whether the vertical position is different from a previously determined vertical position, which may in particular be the nominal vertical position of the light module.

If the vertical position of the light module is identical to the previously determined vertical position, the method returns to step 601 until updated sensor information is received. Alternatively, the sensor information can be received continuously, and the light module implements step 602 at regular intervals, or upon detection of a significant variation in the information received.

If the vertical position of the light module differs from the previously determined vertical position, the light module modifies, in a step 604, the nominal supply setpoint of the matrix source, according to the vertical position determined in the previous step. , or determined vertical positions. The modifications made may consist of a modification of the first set of pixels activated on the matrix source and/or a modification of the duty cycles of a group of pixels of the first set, in accordance with the explanations previously given.

[0109] In a step 605, the control device can transmit the modified nominal supply setpoint to a device for controlling the supply of the matrix light source. Alternatively, the light module itself can control the supply of the matrix light source according to the modified command.

As a variant, steps 601 to 604 of the method can be implemented in a control device integrated into a centralized entity of the vehicle, and the modified nominal power supply commands can be transmitted at step 605 to one or several light modules which thus control the supply of their respective matrix light sources.

Figure 7 shows a control device 700 according to one embodiment of the invention. The control device 700 can be integrated into a centralized entity of the vehicle, or can be integrated into a near-field projection light module, such as one of the light modules 101.1, 101.2 and 101.3.

The control device 700 comprises a processor 701 configured to communicate unidirectionally or bidirectionally, via one or more buses or via a direct wired connection, with a memory 702 such as a “Random Access Memory” type memory, RAM, or a “Read Only Memory” type memory, ROM, or any other type of memory (Flash, EEPROM, etc.). Alternatively, memory 702 includes several memories of the aforementioned types.

The memory 702 is capable of storing, permanently or temporarily, at least some of the data used and/or resulting from the implementation of the method according to the invention. In particular, memory 702 can store one or more nominal power commands as well as correspondences between vertical positions and modifications of the nominal power command.

The processor 701 is capable of executing instructions, stored in the memory 702, for the implementation of the steps of the method according to the invention. Of alternatively, the processor 702 can be replaced by a microcontroller designed and configured to carry out the steps of the method according to the invention.

The control device 70 includes a first interface 703 arranged to receive information from sensors during step 601 described above.

The control device 700 further comprises a second interface 704 arranged to transmit the command modified in step 605 described above.

When the control device 700 is a centralized entity, several commands can be generated, a command then being addressed to each of the light modules via the second interface 704, or via an interface dedicated to each light module. In this case, each order can be determined: a. from the vertical position of the light module to which it is addressed; b. from the vertical position of the light module to which it is addressed, and from the vertical position of at least one other light module. Such an embodiment is particularly advantageous in the context of centralized control.

The present invention is not limited to the embodiments described above by way of examples; it extends to other variants.

Claims

22

Claims Method for controlling a matrix light source (102.1; 102.2; 102.3) of a near-field projection light module (101.1; 101.2; 101.3) of a vehicle (100), the method comprising the following operations:

- Obtaining (601; 602) a vertical position of the light module;

- modification (604) of a nominal supply control of the matrix light source according to the vertical position obtained;

- transmission (605) of said modified command for controlling the matrix light source. A method according to claim 1, comprising, upon detection (603) of a change in the vertical position of the light module, updating (604) the change in the nominal power command. Method according to Claim 1 or 2, in which the vertical position of the light module (101.1; 101.2; 101.3) is determined:

- based on information from a sensor dedicated to the light module, and/or;

- from information relating to a shape of a beam of lighting projected by the vehicle, from camera data, and/or

- from inclination information of a lighting module of the vehicle; Method according to one of the preceding claims, in which the nominal command comprises an activation of a first set (301) of pixels (300) of the light module (101.1; 101.2; 101.3) and wherein modifying the nominal command includes modifying the first set of pixels. Method according to one of the preceding claims, in which the nominal control comprises the activation of a first set (301.1; 301.2) of pixels (300) of the light module (101.1; 101.2; 101.3) by a width modulation supply pulse, the nominal command comprising a duty cycle value for each pixel of the first set. Method according to the preceding claim, in which the modification of the nominal command comprises the modification of at least one duty cycle of a pixel of the first set (301) so as to harmonize a light intensity of a beam projected by the light module . Method according to one of the preceding claims, in which the modification of the nominal command comprises the modification of the first set of pixels (301) into a first modified set (302) of pixels, distinct from the first set (301) corresponding to the command nominal power supply, the first modified set (302) comprising additional pixels relative to the first set of pixels (301). Method according to one of Claims 5 and 6, implemented in a vehicle (100) comprising at least a first near-field projection light module (101.1) comprising a first matrix source (102.1), and a second near field projection (101.3) comprising a second matrix source (102.3); wherein a first vertical position is determined for the first light module and/or a second vertical position is determined for the second light module; wherein a first nominal command controls the first matrix source and a second nominal command controls the second matrix source; in which the light module is able to project a first light beam according to the first nominal command and the second light module is able to project a second light beam according to the second nominal command; wherein the first nominal command and/or the second nominal command are modified so as to decrease the luminous intensity of an overlapping zone (404.1) of the first and second projected light beams, as a function of the first vertical position and/or from the second vertical position. A method according to claims 5 and 6, wherein the first nominal command comprises activating a first set (301.1) of pixels (300) of the first matrix source (102.1) by a pulse width modulation supply, and the second nominal command comprises activating a second set (301.2) of pixels of the second matrix source (102.3) by a pulse width modulation supply, and wherein the first nominal command and/or the second nominal command is modified so as to decrease the duty cycle of pixels corresponding to the overlapping area (404.1), in order to decrease the light intensity of the overlapping area. Method according to claim 8 or 9, in which the first nominal command is modified according to:

- from the first vertical position, or

- the first vertical position and the second vertical position. 25 Method according to one of the preceding claims, implemented in a vehicle comprising at least two near-field projection light modules, including a right side light module (101.1) comprising a right matrix source (102.1) and a side light module left (101.2) comprising a left matrix source (102.2), in which a right vertical position is determined for the first light module and a second left vertical position is determined for the second light module; wherein a right nominal command controls the right matrix source and a left nominal command controls the left matrix source; in which the right side light module is capable of projecting a right side light beam according to the first nominal command and the left side light module is capable of projecting a left side light beam according to the second nominal command; wherein the right nominal command is changed according to the right vertical position and the left nominal command is changed according to the left vertical position. Device (700) for controlling a matrix light source (102.1; 102.2; 102.3) of a near-field projection light module (101.1; 101.2; 101.3) of a vehicle (100), the device comprising a processor (701) configured to:

- obtain a vertical position of the light module;

- modifying a nominal supply command of the matrix light source according to the vertical position obtained; 26

- transmitting said modified command for controlling the matrix light source. Vehicle comprising a control device (700) according to the preceding claim.